Method for self-aligned metal gate cmos

ABSTRACT

A semiconductor device is formed by first providing a dual gate semiconductor device structure having FET pair precursors, which includes an nFET precursor and a pFET precursor, wherein each of the nFET precursor and the pFET precursor includes a dummy gate structure. At least one protective layer is deposited across the FET pair precursors, leaving the dummy gate structures exposed. The dummy gate structure is removed from one of the nFET precursor and the pFET precursor to create therein one of an nFET gate hole and a pFET gate hole, respectively. A fill is deposited into the formed one of the nFET gate hole and the pFET gate.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The field of the present invention is semiconductor fabrication, particularly CMOS semiconductor fabrication in which preformed dummy gates are selectively removed.

2. Background

One major drawback of fabricating metal gate CMOS semiconductors using replacement gate or semi-replacement gate methods is the challenges presented by ground rule requirements. Specifically, the n to p spacing, in an SRAM for example, makes removing the dummy gate from one FET while being selective to the other FET difficult at best. However, even with these challenges, certain CMOS fabrication processes may find replacement gate or semi-replacement gate methods advantageous, thereby enabling removal of the dummy gate from one FET while being selective of the other FET.

SUMMARY OF THE INVENTION

The present invention is directed toward a method of forming a semiconductor device in which preformed dummy gates are selectively removed and intermediate semiconductor device products. The semiconductor device includes precursors to a FET pair, and may be a dual gate CMOS structure. The FET pair precursors includes an nFET precursor and a pFET precursor, each of which includes a dummy gate structure. At least one protective layer is deposited across the FET pair precursors, leaving the dummy gate structures exposed. The dummy gate structure is removed from at least the nFET precursor and the pFET precursor, leaving one of an nFET gate hole and a pFET gate hole, respectively. A fill is then deposited within the formed gate hole.

As a further aspect of the method, depositing at least one protective layer may include depositing a first protective layer across the FET pair precursors, depositing a second protective layer onto the first protective layer, and then removing a portion of the first and second protective layers to expose the dummy gate structures. The first protective layer may be a SiN liner, and the second protective layer may be a high density plasma oxide.

As another further aspect of the method, the dummy gate structure of the nFET precursor may include an N-type poly Si, and the dummy gate structure of the pFET precursor may include a P-type poly Si. When removing the dummy gate structure from either of the nFET precursor and the pFET precursor, the dummy gate structure from one of the nFET precursor and the pFET precursor is selectively removed.

As another further aspect of the method, depositing the first fill may include depositing a first conformal film onto the FET pair precursors and removing a portion of the first film to expose the first fill and the dummy gate structure from the other of the nFET precursor and the pFET precursor. This aspect may be achieved by further removing the dummy gate structure from the other of the nFET precursor and the pFET precursor to create therein one of the nFET gate hole and the pFET gate hole, respectively, and depositing a second fill into one of the nFET gate hole and the pFET gate hole. A second conformal film may thereafter be deposited onto the FET pair precursors, then a portion of the second film may be removed to expose the first fill and the second fill.

As another further aspect of the invention, an oxygen treatment may be used to add O₂ to vacancies in a high K material, thereby providing a lower threshold voltage in a pFET by filling in the holes without changing the threshold voltage for the paired nFET.

A first intermediate semiconductor device product includes FET pair precursors disposed on a substrate. One of the FET pair precursors may be an nFET precursor, and the other may be a pFET precursor. One of the FET precursors includes a fill disposed above and in contact with its respective metal gate layer, and the other of the FET precursors includes a dummy gate structure disposed above and in contact with its respective second metal gate later, with the fill and the dummy gate structure sharing a common interface.

A second intermediate semiconductor device product includes FET pair precursors disposed on a substrate, with one of the FET pair precursors being an nFET precursor, and the other being a pFET precursor. Each FET precursor includes spacers disposed on two sides of and extending above a gate stack. Each gate stack is topped by a metal gate layer. A fill is disposed over the pair of FET precursors and between the spacers of each FET precursor. The fill is in contact with each of the metal gate layers. This fill may also extend above the spacers and continuously between the nFET and pFET precursors. The fill may overlay at least one protective layer disposed over parts of the FET precursors, and it may be deposited as a conformal film, such as, for example, a SiN film.

Any of the above aspects of the method may be employed alone or in combination.

Accordingly, an improved method of forming a semiconductor device is disclosed. Advantages of the improvements will appear from the drawings and the description of the preferred embodiment.

BRIEF DESCRIPTION OF THE DRAWINGS

In the drawings, wherein like reference numerals refer to similar components:

FIG. 1 schematically illustrates a semiconductor device structure of the prior art having precursors to a FET pair, which includes dummy gates in each of an nFET precursor and a pFET precursor; and

FIGS. 2A-2J schematically illustrate process steps for forming the semiconductor device of FIG. 1.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Turning in detail to the drawings, FIG. 1 illustrates a conventional semiconductor device structure 110 known in the art having precursors to a FET pair, which includes both an nFET precursor 112 and a pFET precursor 114. This semiconductor device structure 110 is an intermediary product in the fabrication of metal gate CMOS semiconductors. Each of the nFET precursor 112 and the pFET precursor 114 have been prepared with dummy gates 116, 118, the nFET precursor 112 having a capping layer to adjust the nFET threshold voltage like Lanthanum Oxide or other material as is known in the art of making high k semiconductor devices, and the pFET precursor 114 having no capping. The semiconductor device structure 110 is formed on a substrate 120, which may be any suitable substrate for semiconductor-device formation, such as a conventional bulk silicon substrate, a silicon-on-insulator-type (SOI) substrate, and the like. The semiconductor device structure 110 may be used as an intermediary product in the production of a metal gate CMOS. As such, the semiconductor device structure 110 has silicide features 122 formed over source/drain portions 124 formed in the substrate 120, and the nFET precursor 112 includes an N-poly as a first dummy gate 116 formed over a P-well 128 in the substrate 120, while the pFET precursor 112 includes a P-poly as a second dummy gate 118 formed over an N-well 132 in the substrate 120. A shallow trench isolation feature 134 is included within the substrate, separating the P-well 128 and the N-well 132. Each of the nFET precursor 112 and the pFET precursor 114 include spacers 136 on either side of each dummy gate 116, 118, and a metal base layer 138 underlying each dummy gate 116, 118. The particular components and/or materials for this semiconductor device structure 110 are representative of features in CMOS products known within the prior art, and therefore may be substituted for known equivalents.

FIGS. 2A-I illustrate a stepwise process for replacing one or both of the dummy gates illustrated in the semiconductor device structure 110 of FIG. 1. Initially the semiconductor device structure 110 is exposed to a forming gas anneal. The gas mixture may be Hydrogen and Nitrogen, although other mixtures may also be used depending upon the design of the particular CMOS end product. The exposure time may be approximately 30 minutes, and the temperature of the process may be approximately 400-700° C. Again, the time and/or temperature of the forming gas anneal may vary depending upon the design of the CMOS end product.

As shown in FIG. 2A, a SiN liner 140 is then formed across both FETs, followed by a dielectric layer 142. Both the SiN liner 140 and the dielectric layer (SiO₂ for example) layer 142 form protective barriers over the semiconductor device structure 110, and both may be formed by any number of processes known to those of skill in the art. For example, the SiN liner 140 may be formed by plasma enhanced chemical vapor deposition PECVD and the dielectric layer 142 as SiO₂ may be deposited by using High Density Plasma deposition (HDP). The thickness of the SiN liner 140 may be in the range of 20 nm-50 nm, and optionally in the range of 5 nm-120 nm. The thickness of the HDP layer 142 may be in the range of 50 nm-100 nm, and optionally in the range of 20 nm-300 nm.

Next, as shown in FIG. 2B, the HDP layer 142 is planaraized, preferably through a chemical-mechanical planarization process, down to the upper level of the SiN liner 140. This leaves exposed the upper portion of the SiN liner 140, which is the portion disposed above each dummy gate 116, 118. As shown in FIG. 2C, the exposed portions of the SiN liner 140 are selectively etched using well-known reactive ion etching (RIE) processes to expose the two dummy gates 116, 118.

With the two dummy gates 116, 118 exposed, the N-poly is removed, as shown in FIG. 2D, in a process that is selective of the P-poly, i.e., the removal processes do not interact with the P-poly. This removal process leaves an nFET gate hole 144 in the space previously occupied by the N-poly. Alternatively, those skilled in the art will recognize that the P-poly could be removed at this step, with the N-poly being removed subsequently. Removal of the N-Poly stops at the N-metal base layer 138, which will form the base layer of any eventual metal gate that is deposited through subsequent processing after one or both dummy gates are removed. The N-poly may be removed using an etch chemistry, such as NH₄OH or TMAH, or any other chemistry that is selective of P-poly, i.e., acts upon the N-poly, but not upon the P-poly.

A conformal SiN film 146 is then deposited on the semiconductor device structure 110, thereby depositing a SiN fill 148 in the nFET gate hole 144, as shown in FIG. 2E. Next, the conformal SiN is etched, preferably using RIE processes, to remove the SiN film down to the level of the remaining dummy gate, which is shown in FIG. 2F as the P-poly dummy gate 118, leaving behind the SiN fill 148 between the gate spacers 136 of the nFET precursor 112. FIG. 2G shows the semiconductor device structure 110 at this stage of the processing in a top-down view as a first intermediate device product. As can be seen, the SiN fill 148 in the nFET gate hole 144 shares a common interface 152 with the P-poly dummy gate 118. As will be recognized by those of skill in the art, this configuration is unique and may enable as yet unrealized processing options.

At this stage, the other dummy gate, shown as the P-poly dummy gate in FIG. 2F, is exposed and may be removed by processes selective of the SiN fill 138. As indicated above, the N-poly could be removed at this stage, if the P-poly was previously removed. This removal process leaves a pFET gate hole 150 in the space previously occupied by the P-poly, as shown in FIG. 2H. Again, removal of the P-poly stops at the P-metal base layer 138, which will form the base layer of any eventual metal gate that is deposited through subsequent processing. The P-poly may be removed using a dry etch chemistry, such as HBr, or any other chemistry that is selective of the SiN fill previously deposited in the nFET precursor 112. Following formation of the pFET gate hole 150, an oxidation treatment may be applied to the semiconductor device structure 110. As is well-known in the art, an oxidation treatment may be used to add O₂ to vacancies in a high K material, thereby providing a lower threshold voltage in a pFET by filling in the oxygen vacancies. By performing the oxidation treatment at this stage, the threshold voltage of the pFET that is eventually formed may be lowered without changing the threshold voltage for the nFET that is eventually formed from these precursors. The oxygen content of the treatment gas and exposure time may vary depending upon the design needs for the finished CMOS end product. However, since the process disclosed herein results in an intermediary product, the gas mixture and exposure time will generally be addressed based on design needs determined at the time of process implementation.

A conformal SiN film 154 is again deposited on the semiconductor device structure 110, thereby depositing an SiN fill 156 in the pFET gate hole, as shown in FIG. 2I. Each gate hole is now filled with an SiN fill, and the SiN film overlays the entire semiconductor device structure. Thus, the semiconductor device shown in FIG. 2I may be beneficially used as another intermediate semiconductor device product because it has the SiN film as a protective layer overlying the entire structure. The protective layer enables further processing options as will be recognized by those of skill in the art.

As a final step in the preferred process, the conformal SiN is etched, preferably using RIE processes, to remove the SiN film 154 down to the level of the gate spacers 136, leaving the SiN fill 156 between the gate spacers 136 of the pFET precursor 114.

The semiconductor device structure 110 resulting from this final step is shown in FIG. 2J. This semiconductor device structure 110 may be used as an intermediary for fabrication of a CMOS as an end product. When used as such, the SiN fills 148, 156 may be removed by known processes and gate structures may be deposited and/or formed to achieve the desired finished product. This self-aligned process described above enables the removal of nFET and pFET dummy gates independently, which is expected to result in improved work function control for pFETs and reduced parasitic capacitances for both FETs. In addition, the process flow enables an enhanced stress effect by removing the dummy gates after front end of the line processing.

Thus, a method of forming a semiconductor device is disclosed. While embodiments of this invention have been shown and described, it will be apparent to those skilled in the art that many more modifications are possible without departing from the inventive concepts herein. The invention, therefore, is not to be restricted except in the spirit of the following claims. 

1. A method of forming a semiconductor device, the method comprising: providing a dual gate semiconductor device structure having FET pair precursors, including an nFET precursor and a pFET precursor, wherein each of the nFET precursor and the pFET precursor includes a dummy gate structure; depositing at least one protective layer across the FET pair precursors, leaving the dummy gate structures exposed; removing the dummy gate structure from one of the nFET precursor and the pFET precursor to form therein one of an nFET gate hole and a pFET gate hole, respectively; depositing a first fill into the formed one of the nFET gate hole and the pFET gate hole.
 2. The method of claim 1, wherein depositing at least one protective layer includes: depositing a first protective layer across the FET pair precursors; depositing a second protective layer onto the first protective layer; and removing a portion of the first and second protective layers to expose the dummy gate structures.
 3. The method of claim 2, wherein the first protective layer is a SiN liner.
 4. The method of claim 2, wherein the second protective layer is a high density plasma oxide.
 5. The method of claim 1, wherein the dummy gate structure of the nFET precursor comprises an N-type poly Si, and the dummy gate structure of the pFET precursor comprises a P-type poly Si, and wherein removing the dummy gate structure from one of the nFET precursor and the pFET precursor includes selectively removing the dummy gate structure from one of the nFET precursor and the pFET precursor.
 6. The method of claim 1, further comprising, following formation of the pFET gate hole and before depositing the first fill, performing an oxidation treatment.
 7. The method of claim 1, wherein depositing the first fill comprises: depositing a first conformal film onto the FET pair precursors; and removing a portion of the first film to expose the first fill and the dummy gate structure from the other of the nFET precursor and the pFET precursor.
 8. The method of claim 7, wherein the first conformal film comprises a SiN film.
 9. The method of claim 7, further comprising: removing the dummy gate structure from the other of the nFET precursor and the pFET precursor to create therein one of the nFET gate hole and the pFET gate hole, respectively; and depositing a second fill into one of the nFET gate hole and the pFET gate hole.
 10. The method of claim 9, further comprising, following formation of the pFET gate hole and before depositing the first fill, performing an oxidation treatment.
 11. The method of claim 9, wherein depositing the second fill comprises: depositing a second conformal film onto the FET pair precursors; and removing a portion of the second film to expose the first fill and the second fill.
 12. The method of claim 11, wherein the second conformal film comprises a SiN film.
 13. A semiconductor device comprising: a substrate; a pair of FET precursors disposed on the substrate, one of the FET precursors being an nFET precursor and the other being a pFET precursor, wherein each FET precursor includes spacers disposed on two sides of and extending above a gate stack, and each gate stack is topped by a metal gate layer; and a fill disposed over the pair of FET precursors and between the spacers of each FET precursor, the fill being in contact with each of the metal gate layers.
 14. The semiconductor device of claim 13, wherein the fill extends above the spacers of each FET precursor and continuously between the nFET and pFET precursors.
 15. The semiconductor device of claim 14, wherein between the nFET and pFET precursors, the fill overlies at least one protective layer disposed over parts of the FET precursors.
 16. The semiconductor device of claim 15, wherein the at least one protective layer includes a SiN liner.
 17. The semiconductor device of claim 15, wherein the at least one protective layer includes a high density plasma oxide.
 18. The semiconductor device of claim 13, wherein the fill is deposited as a conformal film.
 19. The semiconductor device of claim 13, wherein conformal film comprises a SiN film.
 20. A semiconductor device comprising: a substrate; a pair of FET precursors disposed on the substrate, wherein a first of the FET precursors includes a fill disposed above and in contact with a respective first metal gate layer, and a second of the FET precursors includes a dummy gate structure disposed above and in contact with a respective second metal gate later, with the fill and the dummy gate structure sharing a common interface.
 21. The semiconductor device of claim 20, wherein the fill is SiN.
 22. The semiconductor device of claim 20, wherein one of the FET precursors is an nFET precursor and the other is a pFET precursor.
 23. The semiconductor device of claim 20, wherein the first FET precursor is the nFET precursor.
 24. The semiconductor device of claim 20, wherein the first FET precursor is the pFET precursor. 